active fabrics typically include a plurality of fibers. At least one of the fibers exhibits a change in length or width upon exposure to an external stimulus, such as heat, moisture, or light. The active woven materials can exhibit local transformation, such as creating areas that are tighter or more open, or global transformation, such as changing from flat to curled. The effect is a precise and repeatable change in shape upon exposure to an external stimulus. Embodiments can be employed, for example, in sportswear, compression garments, furniture, and interior products.

Patent
   10633772
Priority
Jan 12 2017
Filed
Jan 12 2018
Issued
Apr 28 2020
Expiry
May 20 2038
Extension
128 days
Assg.orig
Entity
Large
8
156
currently ok
1. An active fabric, comprising:
a plurality of fibers, including active and passive fibers that are woven, knitted, or braided together in an arrangement that forms a shape of an article, wherein at least one active fiber is an active material laminated with a non-active material, whereby the at least one active fiber exhibits a change in dimension responsive to exposure to a stimulus, a differential between the change in dimensions of the active and passive fibers producing an autonomous, predefined physical transformation as a function of the arrangement to the shape of the arrangement or the article.
2. The active fabric of claim 1, wherein the external stimulus is heat, moisture, light, cold.
3. The active fabric of claim 1, wherein the external stimulus is a change in temperature.
4. The active fabric of claim 1, wherein the active fibers are present at a portion of the active fabric to produce a local physical transformation.
5. The active fabric of claim 4, wherein the local physical transformation produces a change in porosity.
6. The active fabric of claim 1, wherein the active fabric exhibits a predefined change of porosity at a location of the plurality of fibers.
7. The active fabric of claim 1, wherein the active fiber is present substantially throughout the active fabric, and wherein the active fabric exhibits global transformation responsive to the stimulus.
8. The active fabric of claim 7, wherein the active fabric changes in three dimensions responsive to the stimulus.
9. The active fabric of claim 1, wherein the active material has a bias, based on extrusion direction of the active material, oriented toward a long axis of the active fiber, and wherein the active fiber curls along its long axis.
10. The active fabric of claim 1, wherein the active material has a bias, based on extrusion direction of the active material, oriented toward a short axis of the active fiber, and wherein the active fiber curls along its short axis.

This application claims the benefit of U.S. Provisional Application No. 62/445,503, filed on Jan. 12, 2017. The entire teachings of the above application is incorporated herein by reference.

Traditionally, three-dimensional structures of a material are either produced by forcing the material into place with thermo-forming, molding or other manual operations, or the three-dimensional structure is produced by the global pattern of the weave/knit/braid itself.

Described herein are active fabrics and methods for creating active fabrics, such as by weaving, knitting, or braiding a combination of materials in order to provide precise and repeatable physical self-transformations by a garment or other article produced with an active fabric in response to a stimulus.

The active fabrics described are formed of a plurality of fibers or linear members woven, knit, or braided into a fabric structure. One or more of the fibers is an active material within the fabric structure that has the capability to autonomously self-transform from one shape into another shape after being subjected to a stimulus (e.g., heat, moisture, UV light or other forms of energy). This transformation can be along the length of the fiber, perpendicular to the length of the fiber, or any angle in between. The combination of multiple active fibers can cause either a local or global transformation. A local transformation potentially creates tighter or more open areas of the woven structure. A global transformation promotes a global shape change of the woven material—e.g., changing shape from flat to curled.

Described herein are active fabrics. The active fabrics includes active and passive fibers in an arrangement. At least one of the active fibers exhibits a change in dimension responsive to exposure to a stimulus, a differential between the change in dimensions producing an autonomous, predefined physical transformation as a function of the arrangement. The fibers of the active fabric can be woven, knitted, or braided. The external stimulus can be heat (e.g., a change in temperature), moisture, or light. The active fibers can be at a portion of the active fabric to produce a local physical transformation. The local physical transformation can produce a change in porosity. The active fabric can exhibit a predefined change of porosity at a location of the plurality of fibers. The active fiber can be present substantially throughout the active fabric, and the active fabric can exhibit global transformation responsive to the stimulus. The active fabric can change in three dimensions responsive to the stimulus.

The foregoing will be apparent from the following more particular description of example embodiments, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating embodiments.

FIGS. 1A-B illustrate a woven material having an active fiber that transforms perpendicular to the length of the woven material. FIG. 1A is a side view of the woven material, and FIG. 1B is a top-down view of the woven material. Upon exposure to an external stimulus, pores of the woven material can increase is size or areas of the woven material can become looser. In FIG. 1B, the active fiber is indicated as a dashed line.

FIGS. 2A-B illustrate a woven material having an active fiber that transforms along the length of the woven material. FIG. 2A is a side view of the woven material, and FIG. 2B is a top-down view of the woven material. Upon exposure to an external stimulus, the woven material curls along a surface of the woven material. In FIG. 2B, the active fiber is indicated as a dashed line.

FIGS. 3A-C illustrate three techniques for forming a woven active fabric having a cylindrical shape. In FIG. 3A, an active fiber winds around the cylinder. The active fiber shrinks along the length of the fiber causing the cylinder to compress in the middle. In FIG. 3B, the active fiber is woven along the cylinder and parallel to the longitudinal axis of the cylinder. When the active fiber transforms in length, the cylinder bulges causing the length to shrink. In FIG. 3C, a first active fiber winds around the cylinder (similar to FIG. 3A), and a second active fiber is woven along the cylinder and parallel to the longitudinal axis of the cylinder (similar to FIG. 3B). When the active fibers are transformed, the woven cylinder can both bulge and compress in different zones. The two active fibers in FIG. 3C can be the same or different.

FIGS. 4A-C are illustrations of three different orientations for weaving an active fiber into a woven cylinder. In each of FIGS. 4A-C, the fibers are illustrated prior to activation (Before) and after transformation (After). In each of FIGS. 4A-C, the active fibers shrink, causing a transformation of the shape of the initial cylinder. In FIG. 4A, the cylinder increases in length and decreases in radius. In FIG. 4B, the cylinder decreases in length and increases in radius. In FIG. 4C, the radius of the cylinder increases at the ends of the cylinder and decreases near the middle of the cylinder.

FIG. 5 is an illustration of an active fabric with active fibers from corner-to-corner.

FIG. 6 is an illustration of an active fabric with two different woven densities and an active fiber running perpendicular to the two zones. When the active fibers shrink, it causes a transformation of the lower-density zone, causing it to curl upward while the higher-density zone remains flat due to the increased stiffness in that zone.

FIG. 7 is an illustration of a knitted active fabric.

A description of example embodiments follows.

As used herein, the term “active fabric” refers to fabrics formed by a variety of methods, including woven fabrics, knitted fabrics, and braided fabrics. For example, knitted fabrics can be two-dimensional or three-dimensional. In general, the fibers of the active fabric are mechanically coupled. At least one of the fibers is an active material, which exhibits a change in length or other dimension upon exposure to a stimulus (e.g., increase or decrease of an activation energy). Active fabrics can be formed having a variety of shapes, such as flat sheets or cylinders.

As described more fully below, the particular woven structure and orientation of the active fiber influences the expected transformation of the woven material.

As used herein, the term “local transformation” refers to a transformation of only a portion of an active fabric. As used herein, the term “global transformation” refers to transformation of the entirety or substantially the entirety of an active fabric.

As used herein, an “autonomous transformation” occurs without direct application of mechanical force.

As illustrated in the figures, active fabrics are made from a plurality of fibers. In the figures, the active fibers are shown with dashed lines, and passive (inactive) fibers are shown as solid lines.

The composition and characteristic of the fibers selected plays an important role in the properties of an active fabric (e.g., flexibility, strength, breathability, and waterproofing) and ultimately the physical transformation of the active fabric. Different types of fabric have characteristic directionality and/or flexibility that promotes or constrains transformation of the active material.

The orientation and properties of the active fiber within the fabric can influence global transformations and local transformations of the active fabric. The particular material from which the fiber is made influences the type of activation energy needed to cause transformation of the active fabric.

When the active fabric includes one or more active fibers oriented in only one direction, then the transformation will be based on the axis of the active fiber (e.g., in line with, or perpendicular to, the axis of the fiber). If there are two active fibers arranged in two directions, there will be a combination of forces, and the resultant shape will be based on this combination of fiber orientation, axis of transformation of the fiber, and transformation force. For example, if there are two perpendicular axes of active fibers and both axes curl on themselves perpendicular to their length, then the resultant transformation will be a local transformation that either creates or eliminates porous spacing between fibers, rather than a global transformation, as illustrated in FIGS. 1A-B. Stated differently, the size of the pores can increase or decrease.

If the fibers are designed to transform along the length of their axis and they are woven in such a way as to have two perpendicular directions, then the resulting transformation is more complex. If an active material is laminated with a non-active material such that the active material's bias, based on its extrusion direction, is oriented toward the long-axis of the fiber, then the resultant transformation after activation is a curl along the length of the fiber, as illustrated in FIG. 2A. If an active material is laminated with a non-active material such that the active material's bias, based on its extrusion direction, is oriented toward the short-axis of the fiber, then the resultant transformation after activation is a curl along the short-axis of the fiber, as illustrated in FIG. 1A.

One example embodiment is an active fabric that is square in shape, with woven fibers, and having two active fibers oriented toward opposing corners of the square active fabric. When the active fibers are exposed to an activation energy, then a global transformation of the shape of the active material occurs that pulls the corners inward to create a rolled-pyramid shape. An example of such a transformation is illustrated in FIG. 5.

The global structure of the weave can influence flexibility and stiffness of the fabric, or help promote certain areas of transformation, regardless of the active material. For example, if active fibers are woven such that certain areas that are fabric are more elastic than others, or certain areas have directional freedom and other areas are constrained, then the active transformation will be a result of those global woven parameters, not only based on the active fiber strength and orientation. As an example, certain zones of the fabric can be constrained by the weave (e.g., locked and can't move). As another example, certain areas of the fabric are more stiff with thicker fibers. As another example, certain areas of the fabric are more densely woven. In these examples, other areas transform more than the areas that are constrained. One way of implementing these examples is to take a square piece of fabric where half of it is woven with a stiffer, more dense weave, and the other half is made with a more flexible and less dense weave. Even with uniform active fibers through the entire fabric, the more flexible/less dense region exhibits greater transformation than the dense/stiff region.

In some embodiments, active fibers are incorporated into a woven, knit, or braided pattern to provide a three-dimensional self-transformation upon exposure of the active fabric to a stimulus (e.g., increase or decrease of energy). The thickness, width, strength, flexibility and pattern of the weave, knit, or braid, in relation to the global weave/knit/braid pattern and its flexibility/stiffness, dictates the precise structure produced after transformation.

Typically, the active fiber transforms along a particular axis. For example, the transformation can occur parallel to the length of the fiber or perpendicular to the length of the fiber. Typically, the transformation is an increase or decrease in length of the active fiber, or a curling of the fiber. The axis of activation of the active fiber can influence the type of transformation.

FIGS. 1A-B and 2A-B illustrate two embodiments of active fabrics. In both embodiments, two fibers are woven in a plain weave, in which the two fibers are oriented approximately perpendicular to each other. One of the fibers is a standard flexible fiber, and the other fiber is an active fiber.

In the embodiment of FIGS. 1A-B, the active fiber curls (e.g., rolls, as illustrated) along the length of the fiber. Upon exposure to an external stimulus, pores of the woven material can increase is size or areas of the woven material can become looser.

In the embodiment of FIGS. 2A-B, the active fiber shrinks along its length upon exposure to heat. After weaving, when the active fabric is exposed to heat, the active fabric curls along the axis of the active fiber due to the shrinkage of the active fiber. After weaving, when the active fabric is exposed to heat, the active fabric curls along the axis of the active fiber due to the shrinkage of the active fiber.

In another embodiment, one of the fibers is a standard flexible (e.g., passive) fiber, and the other fiber is an active fiber that expands perpendicular to its length upon exposure to moisture. This active fiber is woven in a “curled” state where the fiber is curled upon itself perpendicular to its length. The woven structure can be created to be porous with twice the space needed between the active fibers by leaving a gap between fibers, which allows the active fibers to expand and fill the gap. After weaving, when the structure is subject to moisture, the woven structure will not change globally, rather locally, the active fiber will un-curl and close the spacing between fibers such as to close the pores and create water-proofing.

In FIG. 3A, the active fiber shortens along the length of the fiber causing the cylinder to compress in the middle. In an alternative embodiment similar to FIG. 3A, the active fiber curls, causing the cylinder to spiral tighter. In comparing FIGS. 3A and 3B, the active fiber of FIG. 3A can be more tightly wound around the middle section. Alternatively, the active fiber of FIG. 3A is selectively activated so that transformation only occurs in the middle. As another alternative, the two ends of the cylinder are constrained so that they cannot change diameter. As a result, the spiral fiber would have more effect on the middle of the cylinder rather than the ends which are constrained.

In FIG. 3C, a first active fiber winds around the cylinder (similar to FIG. 3A), and a second active fiber is woven along the cylinder and parallel to the longitudinal axis of the cylinder (similar to FIG. 3B). When the active fibers are transformed, the woven cylinder can both bulge and compress in different zones. The two active fibers in FIG. 3C can be the same or different. Alternatively, only selective regions can be activated (rather than the entire fiber/cylinder), for example, the middle of the wound active fiber could be activated while the two sides of the longitudinal fiber are activated causing the variable bulging and compression. As another alternative, the ends of the cylinders can be constrained so that they cannot change in diameter, causing the cylinder to undulate when the fibers are activated.

Examples of fibers that expand or contract along their length upon exposure to a change in temperature include NYLON, polyethylene (PE), polyvinylidene fluoride (PVDF), polyester, and polytetrafluoroethylene (PTFE).

Examples of fibers that expand or contract perpendicular to their length upon exposure to moisture include cellulose, nylon, and wool.

Examples of fibers that transform upon exposure to light include polystyrene.

Activation Stimulus

The type, amount, and location where an activation stimulus (e.g., energy) is applied to the active fabric can influence the transformation characteristics based on the pattern and amount of active material.

For example, if a minimal amount of heat-activated fiber is incorporated into the structure and then heat is applied to the entire woven material, a local transformation will occur based on the location and direction of the heat-activated fiber. Portions of the active fabric that do not include an active fiber should not respond to the heat. Only the heat-activated fibers will transform (e.g., shrink), causing local transformation, based on their axis of transformation and their orientation in the woven structure.

If the entire active fabric is created with heat-activated fibers, then a very different transformation can occur if the entire composite is subject to heat. One example is a global curling shape, rather than local transformation. However, if the heat is locally applied to the active fabric, rather than to the entire active fabric, then a local transformation may occur. This demonstrates that the location of the applied energy can directly impact the nature of the transformation (e.g., local vs. global).

The amount of activation can cause different transformation characteristics. For example, if more heat is applied in a short amount of time, the rate of transformation can increase, depending on the active material's characteristics. The length of time the active fabric is exposed to the activation energy can also impact the shape transformation, where a longer exposure to the activation energy can produce a different shape by allowing the material to transform more than if the activation energy was applied only for a short amount of time.

Different types of activation energy, in relation to the active material, can cause different transformation characteristics. For example, water-activated materials often tend to transform more slowly and less repeatably compared to heat-active material. Light-active material typically tend to react more quickly, but the transformation tend to be irreversible or have less force whereas heat-active material may be completely repeatable. The location and type of active material based on the supplied activation energy allows for many different transformations with different activations energies, at different times and should be designed specifically for the application and environment of use.

Resultant Shape Transformation

The three-dimensional shape of a transformed active fabric is a result of the careful design of: 1) the material property of the non-active fiber or fibers; 2) the material property, amount and pattern of the active fiber or fibers; 3) the global pattern of the fabric structure and its local/global constraints; and 4) the amount, pattern and time of supplied activation energy. This relationship can be simplified and easily controlled if a single type of non-active fiber, a single type of active fiber, and a single type of activation energy are used. This leaves only the pattern and quantity of the active fiber, thus the pattern becomes the “program” for creating precise self-transforming woven materials.

The active fabrics allow for precise control over three-dimensional self-transformations for active fabrics. Complex, precise and pre-determined shapes can be achieved such as material detailing, patterning and fashion/apparel texturing (ripple patterns, tufting, pleating etc) or larger repeatable transformations for comfort (sinusoidal waves, various degrees of positive and negative curvature, cut/vents etc), custom fit or openings (porosity, breathability, water-proofing). This method produces predictable and unique geometric structures from a traditionally passive, flat, woven material opening new opportunities for a variety of products and industrial manufacturing processes.

A sinusoidal structure can be created by alternating the orientation of the curl of the active fiber: top and bottom, top and bottom, along the length of the fabric. Vents are similar to the porosity embodiments except that the fabric can have cuts or slits that allow specific regions to curl open or closed when the active fabric in that region is activated. Changes in water permeability can be implemented by an embodiment where the material closes to minimize holes and stop water and then opens to be breathable again.

The active fabrics described herein confer significant advantages compared to traditional methods of making complex geometry, curvature or detailing in flat woven materials. Traditionally, three-dimensional structures of a material are either produced by forcing the material into place with thermo-forming, molding or other manual operations, or the three-dimensional structure is produced by the global pattern of the weave/knit/braid itself. Improved fabrics capable of providing a three dimensional structure are desirable. As described herein, the three-dimensional structure can be produced by self-transformation of active fibers within an active fabric. Thus the active fabric can autonomously create a desired shape when and where the user desires (without manual manipulation). By reducing the manual labor, time and skill required to form woven materials into complex shapes, the active fabrics can provide efficiencies and manufacturing opportunities. The active fabric can now be “smart” and either change shape for performance, comfort or other applications and can change porosity and micro-structure on the fly.

Comparison to Existing Systems

This active fabrics described herein go beyond traditional woven systems as well as traditional smart material sheets to create completely new behaviors in woven or textile structures that can autonomously react to an external environment (e.g., heat, moisture, light, electricity etc). In traditional woven systems passive fibers, strands or other elements are combined to make a textile structure that has passive or mechanical properties, such as stretch, stiffness, or porosity, and does not have active and reversible properties like breathability, shape-transformation, moisture-active water proofing, etc. This active fabrics can provide functional and useful transformation (fiber orientation, weaving pattern, types of active materials vs. passive materials, activation energy, 2D vs. 3D woven structures etc). When an active element is woven in a specific orientation with a specific woven pattern using the correct material, either a local transformation can be created, allowing for smart breathability, porosity, or local shape-transformation, or alternatively, a global transformation can be created where the entire woven surface self-transforms to form around the body or other 3-dimensional complex shape.

Forming & Detailing

Today's manual or automated material forming techniques require significant energy, precision, skill and time to produce unique shapes. Footwear and apparel goods are examples of products that rely on industrial forming techniques to stretch and force material around a physical mold. The physical mold constrains the possible number and complexity of the product since a new mold is needed for each unique product and the molds tend to be expensive, passive and simple due to their CNC-machining process. In contrast, active fabrics described herein allow a single sheet of woven/knit/braided material to self-transform into any arbitrary 2D or 3D structure based a stimulus (e.g., activation energy). In some instances, the mold can be eliminated entirely, reducing the cost and limitations for a single product type. The active fabrics also allows for customizable products to be easily produced and entirely new types of products that would previously not have been possible with a subtractive-milled mold, thus, eliminating the forming or molding techniques entirely.

Comfort and Fit

New products are also now possible that can self-transform and adapt to the user or the type of use and fluctuating environments. Nearly all products are designed to be passive with a single function and fit. For example, shoes or clothing are designed for a single type of use and do not adapt if the user changes from one climate to another, if they start to run versus walk or if they grow or gain/loose weight. Active self-transforming woven materials can now be designed to open or close such as to allow active venting/cooling/heating, transform shape for water proofing or moisture retention and independently morph for added comfort or structure based on the activity. For example, someone might want a loose-fit shirt for everyday use then want a tighter-fit shirt when playing sports. Similar, this shirt may open as the external temperature increases to actively cool the person, or may close when it is cool. The shirt may also open in specific places if the person starts playing a sport or increasing their body temperature. Entirely new product concepts can be created with active self-transforming wovens that can morph their shape or performance based on the user's body, comfort, new design or aesthetic preferences, fluctuating environments and changing functions.

Manufacturing Techniques

Fabrication & Manufacturing: Self-forming techniques may require less energy and may use fewer automated machines. The manufacturing techniques may require less labor and time. Automated process for creating intricate patterns, such as pleating, tufting, and stitching details, can be created with reduced need for manual labor or complex machines. As a results, variable patterns can be formed in 2- or 3-dimensions. Automated process for creating complex curvature (e.g., for the body or foot) without darting, patterning or patching material

Performance Surfaces

Active self-transforming woven materials can also be designed to create dynamic performance increase—including aerodynamics, moisture control, temperature control or other properties that may create competitive advantage. By controlling the shape and resultant flexibility/stiffness and actuation a dynamic woven surface can transform on an athlete to increase or decrease aerodynamic resistance or breathability for higher performance. Similarly, these woven surfaces could dynamically put pressure in various points of the body to increase blood-flow and create active compression garments for athletic or medical benefits.

The active woven materials can be used in a variety of applications.

Sports and performance applications include: self-transformation process for custom fit for footwear or apparel; creating aerodynamic or other performances surfaces with highly dynamic complex shapes/textures/patterns; active compression structures/constraints in footwear and apparel to increase athlete performance by controlled blood flow; active cooling, moisture control or breathability for sportswear, footwear and garments; dynamic apparel or footwear for different environments, dynamic body conditions or varied user performance (e.g., running vs. walking).

Fabrication & Manufacturing: Self-forming techniques may require less energy and may use fewer automated machines. The manufacturing techniques may require less labor and time. Automated process for creating intricate patterns, such as pleating, tufting, and stitching details, can be created with reduced need for manual labor or complex machines. As a results, variable patterns can be formed in 2- or 3-dimensions. Automated process for creating complex curvature (e.g., for the body or foot) without darting, patterning or patching material

Medical and Health applications include: compression garments with various degrees of compression/tension across the body to help circulate blood flow in custom pathways; dynamic support for enhanced strength, walking or other physical maneuvers—in other words, a tunable woven exoskeleton.

Fashion applications include: new capabilities for designing fashion and apparel with shapes and patterns that were impossible or difficult to produce previously; shape and structure can be produced with single sheets of material rather than underlying structure or multiple patched wovens.

Furniture and interior products applications include: self-transforming furniture or other interior products; woven-based complex and 3-dimensional interior partitions and other wall treatments that can be created to self-transform based on fluctuating environments.

The teachings of all patents, published applications and references cited herein are incorporated by reference in their entirety.

While example embodiments have been particularly shown and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the embodiments encompassed by the appended claims.

Tibbits, Skylar J. E., Laucks, Jared Smith, Mairopoulos, Dimitrios

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